Switching regulator

ABSTRACT

A switching regulator includes a first switch; a second switch coupled between the first switch and ground; an inductor coupled to a common node between the first and second switches; a capacitor coupled between the inductor and ground; a controller receiving a disable signal, and generating first and second control signals respectively for the first and second switches; and a crossing detector comparing an auxiliary voltage at the common node with a negative reference voltage to generate a comparison signal, and generating the disable signal based on the first control signal and the comparison signal. The second control signal switches into an inactive state upon the disable signal indicating a reference-crossing of the auxiliary voltage.

FIELD

The disclosure relates to switching regulation, and more particularly toa switching regulator.

BACKGROUND

A synchronous type switching regulator may use a zero-crossing detectorto assist in reducing energy loss from a capacitor thereof. In order tosignificantly reduce the energy loss, the zero-crossing detectorconventionally requires a comparator that operates relatively fast.However, faster operation speed of the comparator leads to more energyconsumption, which is adverse in maximizing efficiency of thesynchronous type switching regulator.

SUMMARY

Therefore, an object of the disclosure is to provide a switchingregulator that can alleviate the drawback of the prior art.

According to the disclosure, the switching regulator includes a firstswitch, a second switch, an inductor, a capacitor, a controller and acrossing detector. The first switch has a first terminal that is used toreceive an input voltage, a second terminal, and a control terminal thatreceives a first control signal. The second switch has a first terminalthat is coupled to the second terminal of the first switch, a secondterminal that is grounded, and a control terminal that receives a secondcontrol signal. The inductor has a first terminal that is coupled to thesecond terminal of the first switch, and a second terminal that is usedto provide an output voltage. The capacitor is coupled between thesecond terminal of the inductor and ground. The controller is coupled tothe control terminals of the first and second switches, receives adisable signal, and generates the first and second control signalsrespectively for the first and second switches. The crossing detectorincludes a comparing module and an output generating module. Thecomparing module is coupled to the second terminal of the first switchfor receiving an auxiliary voltage thereat, further receives a referencevoltage that is negative, and compares the auxiliary voltage with thereference voltage to generate a comparison signal. The output generatingmodule is coupled to the controller and the comparing module forreceiving the first control signal and the comparison signalrespectively therefrom, and generates, for the controller and based onthe first control signal and the comparison signal, the disable signalthat is capable of indicating a reference-crossing of the auxiliaryvoltage at which the auxiliary voltage equals the reference voltage.Each of the first and second control signals switches between an activestate that causes the respective one of the first and second switches toconduct, and an inactive state that causes the respective one of thefirst and second switches to not conduct. The second control signalswitches into the inactive state upon the disable signal indicating thereference-crossing of the auxiliary voltage.

BRIEF DESCRIPTION OF THE DRAWINGS

Other features and advantages of the disclosure will become apparent inthe following detailed description of the embodiment with reference tothe accompanying drawings, of which:

FIG. 1 is a circuit block diagram illustrating a first embodiment of aswitching regulator according to the disclosure;

FIG. 2 is a circuit block diagram illustrating a crossing detector ofthe first embodiment;

FIG. 3 is a timing diagram illustrating operation of the firstembodiment; and

FIG. 4 is a circuit block diagram illustrating a crossing detector of asecond embodiment of the switching regulator according to thedisclosure.

DETAILED DESCRIPTION

Before the disclosure is described in greater detail, it should be notedthat where considered appropriate, reference numerals or terminalportions of reference numerals have been repeated among the figures toindicate corresponding or analogous elements, which may optionally havesimilar characteristics.

Referring to FIG. 1, a first embodiment of a switching regulatoraccording to the disclosure is used to generate a direct current (DC)output voltage (Vout) based on a DC input voltage (Vin), and includes afirst switch 1, a second switch 2, a first inductor 3, a first capacitor4, a controller 5 and a crossing detector 6.

The first switch 1 has a first terminal that is used to receive theinput voltage (Vin), a second terminal, and a control terminal thatreceives a first control signal (CTRL1). In this embodiment, the firstswitch 1 is a P-type metal oxide semiconductor field effect transistor(pMOSFET) having a source terminal, a drain terminal and a gate terminalthat respectively serve as the first, second and control terminals ofthe first switch 1.

The second switch 2 has a first terminal that is coupled to the secondterminal of the first switch 1, a second terminal that is grounded, anda control terminal that receives a second control signal (CTRL2). Inthis embodiment, the second switch 2 is an N-type metal oxidesemiconductor field effect transistor (nMOSFET) having a drain terminal,a source terminal and a gate terminal that respectively serve as thefirst, second and control terminals of the second switch 2.

The first inductor 3 has a first terminal that is coupled to the secondterminal of the first switch 1, and a second terminal that is used toprovide the output voltage (Vout).

The first capacitor 4 is coupled between the second terminal of thefirst inductor 3 and ground.

The controller 5 is coupled to the second terminal of the first inductor3 for receiving the output voltage (Vout) therefrom, is coupled furtherto the control terminals of the first and second switches 1, 2, andfurther receives a disable signal (DISABLE). The controller 5 generates,based on the output voltage (Vout) and the disable signal (DISABLE), thefirst and second control signals (CTRL1, CTRL2) respectively for thefirst and second switches 1, 2.

Further referring to FIG. 3, the first control signal (CTRL1) switchesbetween an active state (e.g., a logic low level) that causes the firstswitch 1 to conduct and an inactive state (e.g., a logic high level)that causes the first switch 1 to not conduct, and has a duty cycle of Dthat is associated with the output voltage (Vout). The second controlsignal (CTRL2) switches between an active state (e.g., a logic highlevel) that causes the second switch 2 to conduct and an inactive state(e.g., a logic low level) that causes the second switch 2 to notconduct, and switching thereof into the inactive state is associatedwith the disable signal (DISABLE).

In this embodiment, as shown in FIG. 3, the first and second controlsignals (CTRL1, CTRL2) have the same switching period of Ts. When one ofthe first and second control signals (CTRL1, CTRL2) is in the activestate, the other one of the first and second control signals (CTRL1,CTRL2) is in the inactive state. The second control signal (CTRL2)switches into the active state at an end of a predetermined dead timeinterval of Td counting from each instance of the first control signal(CTRL1) switching into the inactive state.

In this embodiment, the controller 5 increases the duty cycle of D whenthe output voltage (Vout) is lower than a predetermined target voltage,and decreases the duty cycle of D when the output voltage (Vout) ishigher than the predetermined target voltage, so as to stabilize theoutput voltage (Vout) at the predetermined target voltage.

In one example, the controller 5 may use pulse width modulation (PWM)techniques to change the duty cycle of D. When the output voltage (Vout)is lower than the predetermined target voltage, the switching period ofTs is unchanged, and an active time interval (equaling Ta) of the firstcontrol signal (CTRL1) is increased, such that the duty cycle of D=Ta/Tsis increased. When the output voltage (Vout) is higher than thepredetermined target voltage, the switching period of Ts is unchanged,and the active time interval (equaling Ta) of the first control signal(CTRL1) is decreased, such that the duty cycle of D=Ta/Ts is decreased.

In another example, the controller 5 may use pulse frequency modulation(PFM) techniques to change the duty cycle of D. When the output voltage(Vout) is lower than the predetermined target voltage, the active timeinterval (equaling Ta) of the first control signal (CTRL1) is unchanged,and the switching period of Ts is decreased, such that the duty cycle ofD=Ta/Ts is increased. When the output voltage (Vout) is higher than thepredetermined target voltage, the active time interval (equaling Ta) ofthe first control signal (CTRL1) is unchanged, and the switching periodof Ts is increased, such that the duty cycle of D=Ta/Ts is decreased.

Referring to FIGS. 1 and 2, the crossing detector 6 includes a referencegenerating module 61, a comparing module 62 and an output generatingmodule 63.

The reference generating module 61 generates a reference voltage (Vref)that is negative.

The comparing module 62 is coupled to the second terminal of the firstswitch 1 for receiving an auxiliary voltage (Vaux) thereat, is coupledfurther to the controller 5 for receiving the second control signal(CTRL2) therefrom, and is coupled further to the reference generatingmodule 61 for receiving the reference voltage (Vref) therefrom. Based onthe second control signal (CTRL2), the comparing module 62 compares theauxiliary voltage (Vaux) during an active time interval of the secondcontrol signal (CTRL2) with the reference voltage (Vref) to generate acomparison signal (COMP).

The output generating module 63 is coupled to the controller 5 and thecomparing module 62 for receiving the first control signal (CTRL1) andthe comparison signal (COMP) respectively therefrom. The outputgenerating module 63 generates, for the controller 5 and based on thefirst control signal (CTRL1) and the comparison signal (COMP), thedisable signal (DISABLE) that is capable of indicating areference-crossing of the auxiliary voltage (Vaux) which occurs duringthe active time interval of the second control signal (CTRL2), and atwhich the auxiliary voltage (Vaux) equals the reference voltage (Vref).

The second control signal (CTRL2) switches into the inactive state uponthe disable signal (DISABLE) indicating the reference-crossing of theauxiliary voltage (Vaux).

In this embodiment, the comparing module 62 includes a third switch 621,a second capacitor 622 and a comparator 623. The third switch 621 (e.g.,an nMOSFET) has a first terminal (e.g., a source terminal) that iscoupled to the second terminal of the first switch 1 for receiving theauxiliary voltage (Vaux) therefrom, a second terminal (e.g., a drainterminal), and a control terminal (e.g., a gate terminal) that iscoupled to the controller 5 for receiving the second control signal(CTRL2) therefrom. The third switch 621 conducts when the second controlsignal (CTRL2) is in the active state, and does not conduct when thesecond control signal (CTRL2) is in the inactive state. The secondcapacitor 622 is coupled between the second terminal of the third switch621 and ground. The third switch 621 and the second capacitor 622cooperatively make a voltage (Vaux2) at the second terminal of the thirdswitch 621 equal to the auxiliary voltage (Vaux) during the active timeinterval of the second control signal (CTRL2), and cooperatively makethe voltage (Vaux2) unchanged otherwise. The comparator 623 has a firstinput terminal (e.g., a non-inverting input terminal) that is coupled tothe second terminal of the third switch 621 for receiving the voltage(Vaux2) thereat, a second input terminal (e.g., an inverting inputterminal) that is coupled to the reference generating module 61 forreceiving the reference voltage (Vref) therefrom, and an output terminalthat provides the comparison signal (COMP). As shown in FIG. 3, thecomparison signal (COMP) switches between a first state (e.g., a logiclow level) which corresponds to that the voltage (Vaux2) is lower thanthe reference voltage (Vref) and a second state (e.g., a logic highlevel) which corresponds to that the voltage (Vaux2) is higher than thereference voltage (Vref). Switching of the comparison signal (COMP) intothe first state is associated with switching of the second controlsignal (CTRL2) into the active state, and lags the switching of thesecond control signal (CTRL2) into the active state in time by a timeinterval of Tp1 due to a finite operation speed of the comparator 623.Switching of the comparison signal (COMP) into the second state isassociated with the reference-crossing of the auxiliary voltage (Vaux),and lags the reference-crossing of the auxiliary voltage (Vaux) in timeby a time interval of Tp2 due to the finite operation speed of thecomparator 623.

In this embodiment, the output generating module 63 includes an inverter631, a first edge detector 632, a second edge detector 633 and an SRlatch 634. The inverter 631 is coupled to the controller 5 for receivingthe first control signal (CTRL1) therefrom, and inverts the firstcontrol signal (CTRL1) to generate an inverted first control signal(CTRL1B). The first edge detector 632 is coupled to the inverter 631 forreceiving the inverted first control signal (CTRL1B) therefrom, anddetects, based on the inverted first control signal (CTRL1B), switchingof the first control signal (CTRL1) into the active state to generate afirst detection signal (DET1). The second edge detector 633 is coupledto the output terminal of the comparator 623 for receiving thecomparison signal (COMP) therefrom, and detects the switching of thecomparison signal (COMP) into the second state to generate a seconddetection signal (DET2). The SR latch 634 is coupled to the first andsecond edge detectors 632, 633 for receiving the first and seconddetection signals (DET1, DET2) respectively therefrom, and generates thedisable signal (DISABLE) based on the first and second detection signals(DET1, DET2). As shown in FIG. 3, the disable signal (DISABLE) switchesbetween a first state (e.g., a logic low level) and a second state(e.g., a logic high level). The SR latch 634 resets the disable signal(DISABLE) to the first state upon the first detection signal (DET1)indicating the switching of the first control signal (CTRL1) into theactive state, and sets the disable signal (DISABLE) to the second stateupon the second detection signal (DET2) indicating the switching of thecomparison signal (COMP) into the second state.

In this embodiment, the reference voltage (Vref) is constant, and ispredetermined in a design phase of the switching regulator. As shown inFIG. 3, the reference voltage (Vref) may be set such that the secondcontrol signal (CTRL2) switches into the inactive state when theauxiliary voltage (Vaux) is negative or that the second control signal(CTRL2) switches into the inactive state when the auxiliary voltage(Vaux) is zero, and such that a current (IL) flowing through the firstinductor 3 is always from one of the first and second switches 1, 2.FIG. 3 depicts a circumstance where the second control signal (CTRL2)switches into the inactive state when the auxiliary voltage (Vaux) iszero. Alternatively, the reference voltage (Vref) may be set such thatthe second control signal (CTRL2) switches into the inactive state whenthe auxiliary voltage (Vaux) is positive and relatively small, and suchthat the current (IL) flowing through the first inductor 3 is from thefirst capacitor 4 in a relatively short time interval.

In this embodiment, the reference generating module 61 is coupledfurther to the inverter 631 and the controller 5 for receiving theinverted first control signal (CTRL1B) and the second control signal(CTRL2) respectively therefrom. The reference generating module 61generates a bias voltage (Vb) that is positive, and converts the biasvoltage (Vb) into the reference voltage (Vref) based on the invertedfirst control signal (CTRL1B) and the second control signal (CTRL2).

In this embodiment, the reference generating module 61 includes a biasgenerator 611, a first resistor 612, a second resistor 613, a fourthswitch 614, a fifth switch 615, a third capacitor 616, a sixth switch617, a seventh switch 618 and a fourth capacitor 619. The bias generator611 generates the bias voltage (Vb). The first resistor 612 has a firstterminal that is coupled to the bias generator 611 for receiving thebias voltage (Vb) therefrom, and a second terminal. The second resistor613 is coupled between the second terminal of the first resistor 612 andground. The fourth switch 614 (e.g., an nMOSFET) has a first terminal(e.g., a source terminal) that is coupled to the second terminal of thefirst resistor 612, a second terminal (e.g., a drain terminal), and acontrol terminal (e.g., a gate terminal) that is coupled to the inverter631 for receiving the inverted first control signal (CTRL1B) therefrom.The fifth switch 615 (e.g., an nMOSFET) has a first terminal (e.g., asource terminal) that is coupled to ground, a second terminal (e.g., adrain terminal), and a control terminal (e.g., a gate terminal) that iscoupled to the inverter 631 for receiving the inverted first controlsignal (CTRL1B) therefrom. The third capacitor 616 is coupled betweenthe second terminals of the fourth and fifth switches 614, 615. Thesixth switch 617 (e.g., an nMOSFET) has a first terminal (e.g., a sourceterminal) that is coupled to the second terminal of the fourth switch614, a second terminal (e.g., a drain terminal) that is grounded, and acontrol terminal (e.g., agate terminal) that is coupled to thecontroller 5 for receiving the second control signal (CTRL2) therefrom.The seventh switch 618 (e.g., an nMOSFET) has a first terminal (e.g., asource terminal) that is coupled to the second terminal of the fifthswitch 615, a second terminal (e.g., a drain terminal) that is coupledto the second input terminal of the comparator 623 for providing thereference voltage (Vref) thereto, and a control terminal (e.g., a gateterminal) that is coupled to the controller 5 for receiving the secondcontrol signal (CTRL2) therefrom. The fourth capacitor 619 is coupledbetween ground and the second terminal of the seventh switch 618. Eachof the fourth and fifth switches 614, 615 conducts when the firstcontrol signal (CTRL1) is in the active state, and does not conduct whenthe first control signal (CTRL1) is in the inactive state. Each of thesixth and seventh switches 617, 618 conducts when the second controlsignal (CTRL2) is in the active state, and does not conduct when thesecond control signal (CTRL2) is in the inactive state. The elements611-619 cooperatively make the reference voltage (Vref) equal to−[R2/(R1+R2)]×Vb, where R1 and R2 respectively denote resistances of thefirst and second resistors 612, 613.

It should be noted that, in other embodiments, the followingmodifications may be made to this embodiment:

1. The third switch 621 and the second capacitor 622 may be omitted. Inthis case, the first input terminal of the comparator 623 is coupled tothe second terminal of the first switch 1 for receiving the auxiliaryvoltage (Vaux) therefrom, and the comparator 623 compares the auxiliaryvoltage (Vaux) and the reference voltage (Vref) to generate thecomparison signal (COMP).

2. The first edge detector 632 may be omitted. In this case, the SRlatch 634 is coupled to the inverter 631 for receiving the invertedfirst control signal (CTRL1B) therefrom, and resetting the disablesignal (DISABLE) to the first state upon the inverted first controlsignal (CTRL1B) indicating the switching of the first control signal(CTRL1) into the active state.

In view of the above, even if the operation speed of the comparator 623is relatively slow, the reference voltage (Vref) can be properlydetermined such that the second control signal (CTRL2) switches into theinactive state when the auxiliary voltage (Vaux) is positive andrelatively small, thereby resulting in a relatively small energy lossfrom the first capacitor 4. Further, the reference voltage (Vref) can beproperly determined such that the second control signal (CTRL2) switchesinto the inactive state when the auxiliary voltage (Vaux) is negative orsuch that the second control signal (CTRL2) switches into the inactivestate when the auxiliary voltage (Vaux) is zero, thereby resulting in noenergy loss from the first capacitor 4.

Referring to FIGS. 1 and 4, a second embodiment of the switchingregulator according to the disclosure is a modification of the firstembodiment, and differs from the first embodiment in that the referencevoltage (Vref) is variable, i.e., not constant.

In the second embodiment, the reference generating module 61 furtherincludes an adjustor 610 that is coupled to the second terminal of thefirst switch 1 and the controller 5 for receiving the auxiliary voltage(Vaux) and the second control signal (CTRL2) respectively therefrom, andthat is coupled further to at least one of the bias generator 611, thefirst resistor 612 or the second resistor 613. The adjustor 610 adjustsat least one of the bias voltage (Vb), the resistance of the firstresistor 612 or the resistance of the second resistor 613 based on theauxiliary voltage (Vaux) and the second control signal (CTRL2), so as tochange the reference voltage (Vref), and in such a manner that thesecond control signal (CTRL2) switches into the inactive state when theauxiliary voltage (Vaux) is zero.

In one example where the adjustor 610 is coupled to the bias generator611 and not to any of the first and second resistors 612, 613, theadjustor 610 decreases the bias voltage (Vb) (i.e., the referencevoltage (Vref) is increased) if the second control signal (CTRL2)switches into the inactive state when the auxiliary voltage (Vaux) isnegative, and increases the bias voltage (Vb) (i.e., the referencevoltage (Vref) is decreased) if the second control signal (CTRL2)switches into the inactive state when the auxiliary voltage (Vaux) ispositive.

In another example where the adjustor 610 is coupled to the firstresistor 612 and not to the bias generator 611 or the second resistor613, the adjustor 610 increases the resistance of the first resistor 612(i.e., the reference voltage (Vref) is increased) if the second controlsignal (CTRL2) switches into the inactive state when the auxiliaryvoltage (Vaux) is negative, and decreases the resistance of the firstresistor 612 (i.e., the reference voltage (Vref) is decreased) if thesecond control signal (CTRL2) switches into the inactive state when theauxiliary voltage (Vaux) is positive.

In yet another example where the adjustor 610 is coupled to the secondresistor 613 and not to the bias generator 611 or the first resistor612, the adjustor 610 decreases the resistance of the second resistor613 (i.e., the reference voltage (Vref) is increased) if the secondcontrol signal (CTRL2) switches into the inactive state when theauxiliary voltage (Vaux) is negative, and increases the resistance ofthe second resistor 613 (i.e., the reference voltage (Vref) isdecreased) if the second control signal (CTRL2) switches into theinactive state when the auxiliary voltage (Vaux) is positive.

In the description above, for the purposes of explanation, numerousspecific details have been set forth in order to provide a thoroughunderstanding of the embodiment. It will be apparent, however, to oneskilled in the art, that one or more other embodiments may be practicedwithout some of these specific details. It should also be appreciatedthat reference throughout this specification to “one embodiment,” “anembodiment,” an embodiment with an indication of an ordinal number andso forth means that a particular feature, structure, or characteristicmay be included in the practice of the disclosure. It should be furtherappreciated that in the description, various features are sometimesgrouped together in a single embodiment, figure, or description thereoffor the purpose of streamlining the disclosure and aiding in theunderstanding of various inventive aspects.

While the disclosure has been described in connection with what isconsidered the exemplary embodiment, it is understood that thedisclosure is not limited to the disclosed embodiment but is intended tocover various arrangements included within the spirit and scope of thebroadest interpretation so as to encompass all such modifications andequivalent arrangements.

What is claimed is:
 1. A switching regulator comprising: a first switchhaving a first terminal that is used to receive an input voltage, asecond terminal, and a control terminal that receives a first controlsignal; a second switch having a first terminal that is coupled to saidsecond terminal of said first switch, a second terminal that isgrounded, and a control terminal that receives a second control signal;a first inductor having a first terminal that is coupled to said secondterminal of said first switch, and a second terminal that is used toprovide an output voltage; a first capacitor coupled between said secondterminal of said first inductor and ground; a controller coupled to saidcontrol terminals of said first and second switches, receiving a disablesignal, and generating the first and second control signals respectivelyfor said first and second switches; and a crossing detector including acomparing module coupled to said second terminal of said first switchfor receiving an auxiliary voltage thereat, further receiving areference voltage that is negative, and comparing the auxiliary voltagewith the reference voltage to generate a comparison signal, and anoutput generating module coupled to said controller and said comparingmodule for receiving the first control signal and the comparison signalrespectively therefrom, and generating, for said controller and based onthe first control signal and the comparison signal, the disable signalthat is capable of indicating a reference-crossing of the auxiliaryvoltage at which the auxiliary voltage equals the reference voltage;wherein each of the first and second control signals switches between anactive state that causes the respective one of said first and secondswitches to conduct and an inactive state that causes the respective oneof said first and second switches to not conduct, and the second controlsignal switches into the inactive state upon the disable signalindicating the reference-crossing of the auxiliary voltage; wherein saidcrossing detector further includes a reference generating module that iscoupled to said comparing module, and that generates the referencevoltage for said comparing module; wherein said output generating moduleinverts the first control signal to generate an inverted first controlsignal; wherein said reference generating module is coupled further tosaid output generating module and said controller for receiving theinverted first control signal and the second control signal respectivelytherefrom; wherein said reference generating module generates a biasvoltage that is positive, and converts the bias voltage into thereference voltage based on the inverted first control signal and thesecond control signal; wherein said reference generating module includesa bias generator generating the bias voltage, a first resistor having afirst terminal that is coupled to said bias generator for receiving thebias voltage therefrom, and a second terminal, a second resistor coupledbetween said second terminal of said first resistor and ground, a thirdswitch having a first terminal that is coupled to said second terminalof said first resistor, a second terminal, and a control terminal thatis coupled to said output generating module for receiving the invertedfirst control signal therefrom, a fourth switch having a first terminalthat is coupled to ground, a second terminal, and a control terminalthat is coupled to said output generating module for receiving theinverted first control signal therefrom, a second capacitor coupledbetween said second terminals of said third and fourth switches, a fifthswitch having a first terminal that is coupled to said second terminalof said third switch, a second terminal that is grounded, and a controlterminal that is coupled to said controller for receiving the secondcontrol signal therefrom, a sixth switch having a first terminal that iscoupled to said second terminal of the fourth switch, a second terminalthat is coupled to said comparing module for providing the referencevoltage thereto, and a control terminal that is coupled to saidcontroller for receiving the second control signal therefrom, and athird capacitor coupled between ground and said second terminal of saidsixth switch.
 2. The switching regulator of claim 1, wherein thereference voltage is sufficient such that the second control signalswitches into the inactive state when the auxiliary voltage is negativeor such that the second control signal switches into the inactive statewhen the auxiliary voltage is zero.
 3. The switching regulator of claim1, wherein the reference voltage is constant.
 4. The switching regulatorof claim 1, wherein: each of said third and fourth switches conductswhen the first control signal is in the active state, and does notconduct when the first control signal is in the inactive state; and eachof said fifth and sixth switches conducts when the second control signalis in the active state, and does not conduct when the second controlsignal is in the inactive state.
 5. The switching regulator of claim 1,wherein said reference generating module further includes an adjustorthat is coupled to said second terminal of said first switch and saidcontroller for receiving the auxiliary voltage and the second controlsignal respectively therefrom, and that is coupled further to at leastone of said bias generator, said first resistor or said second resistor,said adjustor adjusting at least one of the bias voltage, a resistanceof said first resistor or a resistance of said second resistor based onthe auxiliary voltage and the second control signal in such a mannerthat the second control signal switches into the inactive state when theauxiliary voltage is zero.
 6. The switching regulator of claim 1,wherein: said comparing module is coupled further to said controller forreceiving the second control signal therefrom; and based on the secondcontrol signal, said comparing module compares the auxiliary voltageduring an active time interval of the second control signal with thereference voltage to generate the comparison signal.
 7. The switchingregulator of claim 6, wherein said comparing module includes: a seventhswitch having a first terminal that is coupled to said second terminalof said first switch for receiving the auxiliary voltage therefrom, asecond terminal, and a control terminal that is coupled to saidcontroller for receiving the second control signal therefrom, saidseventh switch conducting when the second control signal is in theactive state, and not conducting when the second control signal is inthe inactive state; a fourth capacitor coupled between said secondterminal of said seventh switch and ground; and a comparator having afirst input terminal that is coupled to said second terminal of saidseventh switch, a second input terminal that receives the referencevoltage, and an output terminal that is coupled to said outputgenerating module for providing the comparison signal thereto.
 8. Theswitching regulator of claim 1, wherein: the comparison signal switchesbetween a first state and a second state, and switching thereof into thesecond state is associated with the reference-crossing of the auxiliaryvoltage; and the disable signal switches between a first state and asecond state, switching thereof into the first state is associated withswitching of the first control signal into the active state, andswitching thereof into the second state is associated with the switchingof the comparison signal into the second state.
 9. The switchingregulator of claim 8, wherein the output generating module includes: aninverter coupled to said controller for receiving the first controlsignal therefrom, and inverting the first control signal to generate theinverted first control signal; a first edge detector coupled to saidinverter for receiving the inverted first control signal therefrom, anddetecting, based on the inverted first control signal, the switching ofthe first control signal into the active state to generate a firstdetection signal; and a second edge detector coupled to said comparingmodule for receiving the comparison signal therefrom, and detecting theswitching of the comparison signal into the second state to generate asecond detection signal; an SR latch coupled to said first and secondedge detectors for receiving the first and second detection signalsrespectively therefrom, coupled further to said controller, andgenerating the disable signal for said controller based on the first andsecond detection signals, said SR latch resetting the disable signal tothe first state upon the first detection signal indicating the switchingof the first control signal into the active state, and setting thedisable signal to the second state upon the second detection signalindicating the switching of the comparison signal into the second state.